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引用本文:陈思祥,杨正健,王从锋,魏辰宇,刘德富.一种气泡释放过程连续监测方法及其在三峡水库香溪河CH4通量监测的应用.湖泊科学,2023,35(5):1659-1669. DOI:10.18307/2023.0526
Chen Sixiang,Yang Zhengjian,Wang Congfeng,Wei Chenyu,Liu Defu.A method for continuous monitoring of the ebullition process and application to methane flux variations in Xiangxi Bay, Three Gorges Reservoir. J. Lake Sci.2023,35(5):1659-1669. DOI:10.18307/2023.0526
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一种气泡释放过程连续监测方法及其在三峡水库香溪河CH4通量监测的应用
陈思祥1,2, 杨正健1,2, 王从锋1,2, 魏辰宇1,2, 刘德富2,3
1.三峡大学水利与环境学院, 宜昌 443002;2.三峡大学三峡水库生态系统湖北省野外科学观测研究站, 宜昌 443002;3.湖北工业大学河湖生态修复及藻类利用湖北省重点实验室, 武汉 430068
摘要:
气泡释放是天然水体释放CH4的主要途径之一,准确量化水体气泡释放量对于辨析其“汇、源”特性至关重要。自然水体释放气泡的不连续性、不确定性使得监测其过程较为困难。本研究针对水体气泡释放监测难题,通过改进倒置漏斗型气泡通量监测装置提出了一种气泡释放过程连续监测方法。本方法测量对象为定长时间监测水域释放气泡的体积,经室内外实验验证,其理论量程为3.6~132 mL/(m2·min),测量结果能够较好的表征10~40 m水深缓流水体气泡体积通量变化特征。运用该方法于2021年6—11月对三峡水库支流香溪河库湾开展CH4气泡通量连续监测,并分析不同环境因子对其产生的影响。结果表明:监测期间,研究水域CH4气泡通量变化范围为0.02~8.13 mg/(m2·d),且各采样点间CH4气泡通量呈现较高的时空变异性;CH4气泡通量与水温、水体pH呈显著正相关关系,与水深及水体电导率呈显著负相关关系。其中,水深可能是决定水体是否通过气泡形式释放CH4的重要影响因素,水深超过38.35 m后水体可能不再通过气泡形式释放CH4。然而,这一水深阈值是否同样适用于三峡水库其它支流还需要更多实验验证。本研究对于揭示三峡水库典型支流气泡态CH4排放过程具有重要意义。
关键词:  气泡释放  监测方法  三峡水库  香溪河库湾  CH4气泡通量
DOI:10.18307/2023.0526
分类号:
基金项目:国家自然科学基金项目(52079075)资助。
A method for continuous monitoring of the ebullition process and application to methane flux variations in Xiangxi Bay, Three Gorges Reservoir
Chen Sixiang1,2, Yang Zhengjian1,2, Wang Congfeng1,2, Wei Chenyu1,2, Liu Defu2,3
1.College of Hydraulic & Environmental Engineering, China Three Gorges University, Yichang 443002, P.R. China;2.Three Gorges Reservoir Ecosystem Field Scientific Observation and Research Station, China Three Gorges University, Yichang 443002, P.R. China;3.Key Laboratory of Ecological Remediation of Lakes and Rivers and Algal Utilization of Hubei Province, Hubei University of Technology, Wuhan 430068, P.R. China
Abstract:
Ebullition is one of the main pathways for the release of CH4 from natural water bodies. It is important to accurately quantify the amount of ebullition in water bodies in order to distinguish between their ‘sink’ and ‘source’ characteristics. However, the discontinuity and uncertainty of ebullition in natural waters make it difficult to monitor the process. To meet the challenge of ebullition monitoring, a method for continuous monitoring of the ebullition process has been proposed by improving the inverted funnel bubble flux monitor. The measurement object of this method is the volume of bubbles released in the monitored water area during a fixed period of time. The theoretical range of this method is 3.6-132 mL/(m2·min) through indoor and outdoor experiments, and the measurement results can better characterize the variation characteristics of ebullitive flux in the slow-flowing water body with the depth of 10-40 m. This method was applied to continuously monitor methane ebullitive flux in Xiangxi Bay, Three Gorges Reservoir, and the influences of various environmental factors on methane ebullitive flux were analyzed. The results showed that during the measurement period, the variation range of methane ebullitive flux was 0.02-8.13 mg/(m2·d), and the ebullitive flux between sampling points showed high spatial-temporal variability. The ebullitive flux was positively correlated with water temperature and pH, and negatively correlated with water depth and conductivity; moreover, water depth might be an important factor in determining whether CH4 was released by ebullition: after the water depth exceeded 38.35 m, the ebullitive flux was below 0.38 mg/(m2·d). However, whether the threshold value (38.35 m) was applicable to other tributaries of the Three Gorges reservoir requires further experimental verification. This study is useful to reveal the emission process of CH4 bubbles in typical tributaries of the Three Gorges Reservoir.
Key words:  Ebullition  monitoring method  Three Gorges Reservoir  Xiangxi bay  methane ebullitive flux
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